CZ300853B6 - Cable terminal - Google Patents

Abstract

In the present invention, there is disclosed a cable terminal (8), in particular outdoor terminal for an electrical cable (10) having a cable conductor (12), a cable insulation (14), a conductive layer (15) and a cable shield (11), the terminal (8) being mounted at one end on a base fitting (20), having means (18) on the base fitting (20) for fastening the cable (10), having an electrical feedthrough (32) in the interior of the terminal (8), having a top fitting (70) for fastening an electrical conductor to the feedthrough (32), having means (30) for electrically connecting the cable shield (11) to earth potential, having a field control device (34,36) and a field insulating device for the potential transitions at the cable (10) end, having an insulating body (50) and having means (23) for fastening the insulating body (50) to the base fitting (20), the electrical feedthrough (32) being connected to the cable conductor (12) via contact elements (17,30), characterized in that the contacts (17,30) are designed as clamping elements, in that the insulating body (50) is filled up with material from the region of the fastening (23) to the base fitting (20) up to the level of the contacts (17) and the filling is reduced towards the top fitting (70), such that an internal cavity (56) is formed, and the insulating body (50) is designed to take up mechanical load on the terminal (8), and in that the surface of the insulating body (50) is coated with a voltage-dependent field-controlling layer (64).

Description

(57)

The cable terminal (8), in particular an outdoor cable terminal (10) with a cable conductor (12), a cable insulator (14), a conductive layer (15) and a cable shield (11), is one side mounted on the foot fitting (20) . It is provided with means (18) on a foot (20) for fastening the cable (10), with an electrical insulating bushing (32) inside the terminal, with an armature (70) head for fastening the electrical conductor with the insulating bushing (32). means for electrically connecting the shielding (11) of the cable to ground potential, to the field control device and to the insulating field device for the potential transitions at the cable end (10), to the insulating body (50) and means for securing the insulating body (50) to the fitting (20) bats. The electrical insulating bushing (32) is connected to the cable conductor (12) via contact members (17, 30) which are designed as clamping members. The insulating body (50) is filled between the fastening region on the shoe fitting (20) up to the height of the contact members (17) and the material is reduced towards the fitting (70) of the head, thereby creating an internal hollow space (56). The insulating body (50) is designed to absorb the mechanical stresses applied to the terminal (8). The surface of the insulating body (50) is lined with a field control coating (64) depending on the voltage.

Cable termination

Technical field

BACKGROUND OF THE INVENTION The invention relates to a cable terminal, in particular an outdoor cable terminal, with cable conductor, cable insulation, conductive layer and cable shield, the terminal being one side mounted on the foot fitting, with means on the foot fitting for cable mounting. , with head fitting for fixing the electrical conductor with insulating bushing, with means for electrically connecting the cable shield to earth potential, with field control device and with field insulating device for potential transitions at the cable end, with insulating body and means for fastening the insulating body on a foot fitting, the electrical insulating bushing being connected to the cable conductor via contact members.

BACKGROUND OF THE INVENTION

The terminals are known in various embodiments. Older embodiments are provided with porcelain insulators and an oil or other chemical charge. Such terminals have the disadvantage that they are not mechanically very robust and no longer meet today's environmental conditions due to possible leakage of substances. The terminal without oil filling is shown in EP 667 665 B1. A special feature of this terminal is a rigid conductive member that is designed to absorb transverse forces. The force transmission takes place from the connection of the overhead line, through the rigid conductive element, through the base body comprising the field control device and the insulating device, to the support structure. No coating of the control field is provided on the terminal surface - especially in the region of the rigid conductive member.

Furthermore, a cable end with a self-supporting structure, but without filling of gaseous or liquid insulating medium (EP 0 683 555 A1) is known. Mechanical rigidity is provided by a rigid metal tube or a rigid coated tube that extends over the entire length of the terminal between the mounting platform and the free conductor clamp. When replacing the cable, the entire structure must be dismantled, in particular the loosening of the loose conductor. This loose conductor is particularly disadvantageous since installation work must be carried out at both the lower and upper ends of the terminal.

With respect to the conductive coating of the support tube, it should be noted that the conductive coatings serve to achieve an equalization of the electric field. For this purpose, it is known to provide such layers of thin conductive material or of semiconductive plastic layers. One particular form of conductive coating is found in FR.2 547 451 A1, where conductivity is non-linearly voltage-dependent.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is an object of the invention to provide a cable terminal, in particular a high voltage outdoor cable terminal, which is cheap to manufacture, mechanically stable and electrically reliable to operate.

This is accomplished by a cable termination, in particular an outdoor cable termination with a cable guide, cable insulation, conductive layer and cable shield, the terminal being mounted on one side of the foot fitting, with means on the foot fitting for cable fastening, with electrical insulating bushing inside. terminals, with head fitting for securing the electrical conductor with insulating bushing, with means for electrically connecting the cable shield to earth potential, with field control device and with field insulating device for the potential end of the cable, with insulating body and means for fastening the insulating body to the electrical insulating bushing is connected to the cable conductor via contact members, according to the invention, the principle of which is that the contact members are formed as clamping members, that the insulating body is between the mounting area on the shoe fitting y is filled up to the height of the contact members with material and the cartridge is reduced towards the head fitting, thereby creating a hollow space lying inside, that the insulating body is designed to absorb mechanical stresses on the terminal, and that the insulating body surface is coated voltage.

According to a preferred embodiment, the control field coating is based on micro-resistors. The microvaristors are preferably zinc oxide microvaristors.

The control field coating preferably extends over the entire length of the insulating body.

The end piece is thus positioned on one side of the flange fitting, preferably for mounting on a traverse. Means for securing the cable with the electrical insulating bushing inside the terminal are provided on the foot fitting. On the head fitting there are means for fastening an electrical conductor with an insulating bushing. Thus, there are provided means for electrically connecting the cable shield to the earth potential and field control means, as well as a field insulating device for the potential transitions at the cable end.

The insulating body generally carries on its surface an elastomeric material (preferably of silicone rubber) with a ribbed surface (shielding plates). The length and, in particular, the diameter of the insulating body must be chosen such that sufficient insulation requirements and sufficient insulation requirements are achieved and atmospheric jumps are avoided at full operating voltage. These requirements are preferably improved when the surface of the insulating body is covered with a resistive or refractive control coating.

The insulating body is attached to the foot fitting. This method of fastening corresponds to the prior art (EP 667 665 B1). Other conventional means are used to electrically connect the cable shield to the ground potential, and to the field control (field control body) and insulation at non-homogeneous potential transitions at the cable end. It is essential that the hollow spaces between the cable end and the field control members and the insulating members existing when attached to the shoe fitting are closed by mechanical anchoring with the shoe fitting.

The core of the invention is that the insulating body is filled with material between the fastening areas on the shoe fitting up to the height of the contact members and that filling up to the fitting of the head is prevented, thereby creating a hollow space lying inside.

Three electrical insulating bushings with contact elements, insulating body and head fitting are manufactured separately. The head fitting preferably consists of an electrically conductive swirl plate and an outer conductor connection socket in which the thread can be placed. For fastening the support axis. The electrical insulating bushing, formed as a pipe or as a plurality, is preferably fastened by a welding process (or by other fixed mechanical connection) within the closure plate. The insulating body, consisting of insulating material, is glued into the fitting of the head. The unit thus produced (also referred to as the assembly unit) is lifted on the carrier axis by a crane to the assembly position and lowered from above from the prepared bottom member of the terminal. The dimensions of the members in the lower region of the mounting unit are designed in such a way that they slide into the body on the foot fitting in a self-centering manner when assembled. The electrical insulating bushing also makes contact with the cable conductor by means of contact elements.

Preferably, a cable push-in system is used to secure the contacts; this can be fastened to the cable conductor with screws. The electrical contact to the electrical insulating bushing is mediated by contact lamellae. This plug-in connection is not configured to absorb forces on the terminal. Therefore, in the present arrangement, the insulating body is designed and dimensioned so as to absorb all mechanical forces, the male closure being removed from the mechanical stress. A typical transverse force is assumed to be 5 kN, so the mechanical design must be taken into account for this parameter.

The insulating body is made of a casting resin or other suitable material. The material may be substantially reinforced, for example with glass fibers. From the bottom edge up to the height of the contact members, the insulating body is completely filled with material. A cavity is preferably formed within the insulating body. The cross-section of the cavity (space filling) can be reduced linearly or by a funnel-like curve towards the head fitting. By creating a hollow space, the weight can be kept small, but the thickness may only be reduced to the extent that the bending forces can be absorbed.

In a preferred embodiment, the inner surface of the cavity is lined with a conductive coating. The essential steps of the assembly method are as follows:

- preparation of the cable end, fitting and stripping of the cable conductor, ís - location of the contact clamp on the cable conductor,

- attachment of the superstructure to the foot fitting,

- hoisting by crane of an assembly consisting of an insulating body, a head fitting and an electrical insulating bushing,

- lowering of the mounting unit on the superstructure mounted on the foot fitting,

- the parts are self-centering,

- fixing and clamping of the mounting unit on the foot fitting,

- fastening the external conductor through the current clamp on the head fitting.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments of the overhead line terminal are shown in the figures. They show in detail:

1 shows a first embodiment with a constant outer diameter, FIG. 2 shows a further embodiment with a graduated outer diameter, FIG. 3 shows an embodiment with different outer contours in the right and left half of the figure, and FIG. 4 shows two flange embodiments.

DETAILED DESCRIPTION OF THE INVENTION

The terminal 8 according to the invention - for example for a nominal voltage of 145 kV and with a conductor cross-section of 1200 mm ² - consists of an insulating body 50, preferably a casting resin, which has a hollow space 56 inside it. 12 and conductor insulation) according to the design known to those skilled in the art, the arrangement of the control field members 36 and the insulating members 51 are provided.

The control field body 33 is made of silicone rubber and lies with its control member 36 at the transition area of the conductor insulation and the end of the conductive layer 15. An essential core of the invention is to provide an insulating body 50 with a cylindrical outer profile 59. . In the lower region 53 there is located the control field body 33 and is screwed to the foot member 20 - flange 20 '. In the upper region of the insulating body 50, a hollow space 56 is formed in its interior, the inner surface 54 of which is designed to be electrically conductive. Access of air to the cavity 56 is possible.

The insulating body 50 is bolted in the foot 20 to the base plate or flange on a support pedestal 29 (for example, a crossbar above the support insulator 21). Alternatively, it may be lower

The area of the insulating body 50 is also shaped as a cast body, which can be inserted into the flange.

The high voltage cable 10 is introduced into the lower region of the overhead line terminal 8. Shielding wires Π. The cable 20 is in electrical contact with the flange 20 'of the foot 20, which is placed over the insulators 21 on the mast crossbar.

As mentioned, the diameter of the insulating body 50, in particular in the lower region 53, see FIG. 3, must be dimensioned such that the field strength in all operating states is below the critical value. A relatively large diameter is required as a result of the installation of steering field members. However, the diameter above the field control area may be reduced. However, this assumes that the shielding plates 62 have a conical or graduated contour. However, the cost of shaping the shielding plates 62 with a contour that varies in length is large, so that a configuration with a constant cross section over the entire length of the insulating body 50 is preferred.

The insulating body 50 may consist of two members 51 'and 51 glued together with different material qualities. The bottom member 51, i.e. fastened to the shoe armature up to the height of the contact members on the cable conductor, is exposed - without being covered by shielding plates - to the surroundings; this must be suitable for outdoor use. The member IL 'can be made of a simplified material, since this area is in any case covered with shielding plates 62. For embodiments with shielding plates 62.1 up to the foot fitting 20 below, there is also an external protective covering so that quality can also be used for this area. of a simple insulating material material 50.

The outer contour 59 of the insulating body 50 is preferably cylindrical along its entire length. It is covered with 25 ri 62 shielding plates of RTV- or LSR-silicone rubber. The outer surface beneath the shielding plates 62 may preferably be covered with a field control coating 64. Depending on the design, quality and presence of the coating 64, the insulating body 50 may be constructed with different diameters (larger and lower decreasing in diameter and between them conical transition), see FIG. and 3. The thickness of the layer may be of varying thickness to influence the optimum control effect.

The inner surface 54 of the cavity 56 may be conductive. It can be made by means of a conductive lacquer, a conductive coating 58 applied by means of a plasma, a metal foil, a metallization or a metal mesh embedded in a resin. The surface 54 lies at the high voltage potential. The advantage of this embodiment is that, even in the case of the formation of condensation water in the cavity 56, electrical safety remains guaranteed because the electrical field conditions are uniform at the existing high voltage potential.

The contact fastening housed in the casting resin insulating body 50 includes an end contact member 30 at the lower end of the tube forming an insulating bushing 32 capable of conducting current. The pipe constituting the insulating bushing 32 is guided to the head fitting 70 and fastened there. In the upper region of the terminal 8 there is a mechanically and electrically tight closing lid 21.

In the transition from the fully-constructed base body in the lower region 53 to the hollow space 56, a connection is provided between the cable conductor 12 and the electrical insulation passageway 32. The contact member 30 formed as a connector grips the cable conductor 12 in the lower part. The current flow from the cable conductor 12 is effected via the contact member 7 to the tube forming the insulating bushing 32. Preferably, displaceable contact and clamping members between the cable conductor 12 and the electrical insulating bushing 32 are provided. sealed with O-ring.

In the right half of the drawing in FIG. 3, there is an embodiment of the insulating body 50 with convex reinforcement in the lower region 53. The metal ring 26 inserted to the ground fault can remain inserted with an unchanged diameter in this construction. Shielding plates 62, 1,62.2 may be provided in the convex region 53.

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4A and 4B show different flange shapes. The attachment of the insulating body 50 to the flange 20 'is effected by several screw connections 23 (FIGS. 2 and 3). By tightening the screws, the assembly unit is clamped over the spring members 44 (see FIG. 3) so that the hollow spaces existing in the region of the control field body are completely closed. FIG. 3 shows a conductive connection from the surface of the insulating body 50 to the ground connection 24 on the crossbar 29. On the base 20 of the insulating body 50, a metal ring 26 is placed. 3).

Claims (8)

PATENT CLAIMS 15 1. A cable terminal (8), in particular an outdoor cable terminal (10) with a cable conductor (12), cable insulation (14), a conductive layer (15) and a cable shield (11), the terminal (8) being one side mounted on the foot fitting (20), with means (18) on the fitting (20) foot for fixing the cable (10), with electrical insulating bushing (32) inside the terminal, with fitting (70) head for fastening electrical conductor with insulating bushing (32), with means for 20 electrical connection of cable shielding (11) to earth potential, to field control device and field insulating device for potential transitions at the cable end (10), to the insulating body (50) and means for securing the insulating body (50) to the armature (20) a foot, wherein the electrical insulating bushing (32) is connected to the cable conductor (12) via the contact members (17, 30), characterized in that the contact members (17, 30) are formed as clamping members that: 25, the insulating body (50) is filled with material between the fastening region on the shoe fitting (20) up to the height of the contact members (17) and the filling is reduced towards the head fitting (70), thereby creating a hollow space (56) lying therein. the insulating body (50) is designed to absorb the mechanical stresses applied to the terminal (8), and that the surface of the insulating body (50) is lined with a field-controlling coating (64) as a function of voltage. Cable end according to claim 1, characterized in that the control field coating (64) is based on micro-resistors. 3. The cable termination according to claim 2, wherein the microvaristors are 35 are composed of zinc oxide microvaristors. Cable end according to one of the preceding claims, characterized in that the control field coating (64) extends over the entire length of the insulating body (50). 40 Cable end according to one of the preceding claims, characterized in that the inner surface (54) of the cavity (56) carries a conductive coating (58). Cable end according to one of the preceding claims, characterized in that the insulating body (50) is made of cast resin. Cable end according to one of the preceding claims, characterized in that the electrical insulating bushing (32) is designed as a pipe. Cable end according to one of the preceding claims, characterized in that: 50 that the contact members (17) on the cable conductor (12) are contact plates.